Cathode ray tube screen forming process

ABSTRACT

A PROCESS FOR MAKING A LUMINESCENT SCREEN FOR A CATHODE RAY TUBE TO PROVIDE A DISPLAY OF COLOR INDICIA RELATING TO FIXED AND MOVING OBJECTS IN A SURVEILLANCE SYSTEM EMPLOYING A SPECIFIC RATE OF SCAN. AN INNER LAYER OF A UV EXCITABLE LONG PERSISTENCE PHOSPHOR, HAVING VISIBLE RADIANT ENERGY EMISSION, IS DISPOSED ON A SCREEN SUPPORTING SURFACE. A FILTER LAYER IS HEAT FORMED THEREOVER TO PROVIDE A BARRIER TO THE PASSAGE OF CATHODE RAYS THERETHROUGH. DISPOSED ON THE FILTER LAYER, IN PROXIMAL RELATIONSHIP TO THE CATHODE RAY SOURCE, IS AN OUTER SCREEN LAYER COMPRISING A MIXTURE OF TWO ELECTRON RESPONSIVE PHOSPHORS, ONE HAVING SHORT PERSISTENCE AND RADIANT ENGERY EMISSION IN THE UV REGION OF THE SPECTRUM AND THE OTHER HAVING MEDIUM PERSISTENCE AND VISIBLE RADIANT ENERGY EMISSION.

Jan. 5, 1.971 A. v. GALLARO ET 3,552,989

CATHODE RAY TUBE SCREEN FORMING PROCESS Original Filed Oct. 21, 1965 2 Sheets-Sheet 1 PHOSPHOR BARRIER v PHOSPHOR INVENTORS ANTHONY V. GALLARO &

BZYCE W. VAN NOY ATTORNEY Jan. 5, 1971 v, GALLARO ET AL CATHODE RAY TUBE SCREEN FORMING PROCESS Original Filed Oct. 21. 1965 2 Sheets-Sheet 2 SIGNAL PULSES mwuzkzwEm SIGNAL PULSES mmmzbm mm 7 INVENTORS ANTHONY V. GALLARO &

BRYCE W. VAN NOY 9;. 1 ATTOR NEYI United States Patent U.S. Cl. 11733.5 6 Claims ABSTRACT OF THE DISCLOSURE A process for making a luminescent screen for a cathode ray tube to provide a display of color indicia relating to fixed and moving objects in a surveillance system employing a specific rate of scan. An inner layer of a UV excitable long persistence phosphor, having visible radiant energy emission, is disposed on a screen supporting surface. A filter layer is heat formed thereover to provide a barrier to the passage of cathode rays therethrough. Disposed on the filter layer, in proximal relationship to the cathode ray source, is an outer screen layer comprising a mixture of two electron responsive phosphors, one having short ersistence and radiant energy emission in the UV region of the spectrum and the other having medium persistence and visible radiant energy emission.

CROSS-REFERENCES TO RELATED APPLICATIONS This application is a divisional application of SN. 689,- 227 filed Nov. 21, 1967, now US. Pat. 3,439,208, which in turn is a continuation of an original application S.N. 500,- 085, filed Oct. 21, 1965, now abandoned. All applications have a common assignee. This divisional application contains matter disclosed but not claimed in the original application S.N. 500,085, but disclosed and claimed in the continuation application S.N. 689,227.

BACKGROUND OF THE INVENTION convey direction and rate of movement thereof. Informaj tion of this type is conventionally determined by electronic means such as, for example, by radar equipment wherein pulsed electromagnetic energy is radiated from a rotating antenna to sweep a designated region. When the directed energy impinges against a reflective surface of an object in its path, many of the radiated pulses of the transmitted energy are reflected and returned as echoes to a receiver oriented relative to the transmitter source. Usually, the receiving apparatus utilizes a cathode ray tube as a plan position indicator (PPI) to present a visual display of the received reflected information. In this type of presentation, the repetitive sweep of the electron beam in the tube is normally visible in the form of a moving timebase line of light called a trace which originates at substantially the center of the screen of the tube and extends radially therefrom. Since each successive radially oriented trace occurs slightly to the right of the previous one, the

3,552,989 Patented Jan. 5, 1971 ice trace appears to rotate as a scan in a continuous sweeping clockwise manner in synchronization with the turning antenna through the complete coverage of 360 degrees. There are various types of radar equipment wherein different rates of scan are utilized. In certain equipment, the rate of a complete rotational scan is less than one per second while in others the rate may be many per second.

The echoes from objects appear as bright spots or luminescent pips as the trace sweeps the screen of the tube. The cathodoluminescent screens utilized in this type of CRT display application usually employ phosphors having sufficient lengths of persistence whereby successive scans or sweeps of the electron beam will indicate both fixed and moving objects by either superimposed or separated pips of luminescence. By its characteristic of persistence, the phosphor retains a diminishing afterglow of light from the respective pips after the trace has passed, and upon successive scans, a luminescent pattern is thereby established. However, since the echo information from both fixed and moving objects is similar, it is difficult to rapidly differentiate between stationary and slowly moving objects.

Complex and sometimes bulky electronic moving target indicators have been constructed wherein the incoming echo signal information is fed through a delay line and beat against the scan signal of the succeeding frame in a manner to be degrees out of phase. While this produces a cancellation of the signals reflected from fixed objects, it unfortunately also effects a partial cancellation of the reflected signals from slowly moving objects thus greatly diminishing the screen luminescence of such objects. A visual display embodying a plurality of luminescent indications of differing levels of intensity requires continual interpretative differentiation on the part of the viewing operator. This not only introduces a factor of time delay but also becomes a fatigue inducing aggravation with resultant variations in discernment. In addition, evaluation of luminescent intensities by different individuals assumes significance as a human variant.

OBJECTS AND SUMMARY OF THE INVENTION Accordingly, it is an object of the invention to reduce the aforementioned disadvantages and provide a luminescent information display wherein fixed and moving objects can be quickly and facilely identified.

Another object is to provide a process for making a luminescent display employing a phosphor system wherein fixed and moving objects are distinguishable by different designations of hue.

Another object is to provide a process for making a luminescent display having discernable luminescent characteristics wherein the judgment of differentiation and associated fatigue inducement are reduced to minimums.

Still another object is to provide a process for making a luminescent display device utilizing a phosphor system having radiant energy emissions of detectably different characteristics.

A further object is the provision of a process for making a luminescent display device that can be expeditiously and inexpensively fabricated and one that can be adapted to mobility with a minimum amount of associated equipment.

The foregoing objects are achieved in one aspect of the invention by the provision of a process for making the screen of a cathode ray tube comprising a phosphor system which when used in a surveillance display device will differentiate between fixed and moving objects by a substantial change in hue. The fabrication of such a screen is achieved by utilizing a process which comprises disposing a continuous layer of a radiant energy excitable phosphor on a screen supporting surface, heat forming a selective barrier filter thereover, and thence disposing a discrete 3 mixture .of two electron responsive phosphors over the filter layer to form a second continuous screen layer. Cooperation of the respective phosphors which have different persistences and different luminescent emissions provide the desired screen characteristics of the display device.

For a better understanding of the present invention together with other and further objects, advantages and capabilities thereof, reference is made to the following specification and appended claims in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross sectional view partially illustrating a cathode ray tube and an embodiment of the screen structure of the invention;

FIG. 2 is a cross sectional view showing another embodiment of the screen structure of the invention;

FIG. 3 is an enlarged cross sectional portion of the screen shown in FIG. 2 diagrammatically illustrating color screen excitation by signal information from a fixed object;

FIG. 4 is an illustration similar to FIG. 3 diagram matically showing color screen excitation by signal information from a moving object;

FIG. 5 is a growth-decay curve showing the relationship between the excited luminescent phosphors as illustrated in FIG. 3;

FIG. 6 is a growth-decay curve showing the relationship between the excited luminescent phosphors as por trayed in FIG. 4; and

FIG. 7 is a plan view of the observable face portion of the display tube showing luminescent patterns of fixed and moving objects.

DESCRIPTION OF THE PREFERRED EMBODIMENTS In this specification, persistence of a phosphor is defined as the period of duration, after cessation of excitation wherein the afterglow or phosphorescence diminishes to 10 percent of initial brightness. In a broad definition of persistence, in accordance with current usage, a very long persistence is considered to be in excess of about one second, a long persistence from about 100 milliseconds to one second, a medium persistence from about one millisecond to 100 milliseconds, and a short persistence less than about one millisecond. Usually the time factor involved for the growth or buildup of luminescence during excitation is somewhat similar to the persistence of afterglow, i.e., a phosphor having long persistence usually is characterized by a slow or long buildup of luminance under excitation. Thus, the term persistence when applied to a phosphor, is normally considered to be also indicative of the type of luminescent buildup involved. Also in this specification, use is made of the adjectival comparatives shorter and longer to indicate comparative degrees of persistence; such terms are not intended to be limiting or definitive in light of the aforementioned definition.

In one embodiment of the invention differentiation between fixed and moving objects is provided by two electron excited phosphors, contained in a common layer, each having a complementary luminescence and a different persistence.

With reference to the drawings, there is shown in FIG. 1 a cathode ray tube 11 having an envelope 13 comprising neck, funnel and face panel portions 15, 17, and 19 re spectively. Within the neck portion there is oriented an electron gun or beam source 21 from which emanates an electron beam 23 directed to impinge upon a luminescent screen 25 which is capable of exhibiting differential color displays to be fully described later in this specification. The construction is applicable to cathode ray tubes of various screen sizes. For descriptive purposes, a suitable example is a 5 AD series tube having a 5 inch screen and an anode voltage within an approximate range of 1 to 3 kv. The screen can be formed on the inner surface of the face portion of the tube or on a. separate substrate positioned within the envelope relative to the face portion. In the embodiment shown, the screen is suitably disposed on the support surface of a substantially transparent support medium 27 compatibly positioned within the face panel 19 by means not shown.

The luminescent screen layer 25 comprises a homogeneous mixture of at least two phosphorus having substantially different times of persistence and radiant energy emis sions of detectably different characteristics. In this instance, the homogeneous mixture comprises two electron excitable phosphors, which, for pictorial clarity, are denoted as separate blocks 31 and 35 in screen 25 in FIG. 1. One of these phosphors 31 is a material having a shorter persistence, for example one such as ZnS:Cu which is classified as P2 by the Joint Electron Devices Engineering Council (J EDEC) and is a medium persistence phosphor. This material exhibits a luminescent emission in substantially the yellow-green wavelength region of the electromagnetic spectrum. The other phosphor component 35 in the screen mixture is one designated as having a longer persistence, for example one such as KMgF :Mn material which is JEDEC classified as P19 long persistence phosphor having a luminescent emission in substantially the orange-red wavelength portion of the spectrum.

The two phosphors are mixed according to weight proportions, for example, the mixture comprises about 15 to 25 percent of the shorter persistence material combined with about to 8-5 percent of the longer persistence phosphor. Screen deposition is accomplished by conventional procedure.

Signals from moving objects produce a moving pattern on the screen 25 wherein the shorter persistence phosphor is quickly excited to produce a sequence of greenish colored pips of diminishing brightness indicative of the movement of the object. The repetitive signals echoed from a fixed object produces excitation of both the shorter and longer persistence phosphors. The complementary emissions therefrom are additive to provide a substantially white luminescent pattern of the fixed object. Thus, the rate of buildup and persistence of the longer persistence phosphor component 35 determines the rate of scan which will provide the desired differential color shift in the display. In the afore-described embodiment, the scan rate should desirably be in excess of twelve scans per second.

Since slower scan rates are often desired for certain radar applications, another embodiment of the invention satisfying this desire will be described in detail.

With reference to FIGS. 2, 3, and 4, a multilayered screen structure 25' is oriented, within envelope 13 of cathode ray tube 11, in a manner similar to that employed for screen 25 in FIG. 1. The multilayer screen 25' comprises an inner layer 39 disposed on the surface of the support medium 27 in the form of a radiant energy excitable phosphor 41 having visible radiant energy emission. Over this inner screen layer a selective barrier layer 43, impervious to the electron beam 23, is applied as an overlay; then a final or outer screen layer 47 oriented in proximal spaced relationship to the electron beam source 21, is applied in a uniform manner over the barrier layer. This outer screen layer comprises a mixture of two electron excitable phosphors 49 and 51 each having a different persistence. One of these, designated as the first phosphor 49 emits radiant energy of a first wavelength in predominately the ultraviolet regions, while the other or second phosphor 51 provides radiant energy of a second wavelength in the visible portion of the spectrum. The bar rier filter layer 43 is transparent to the radiant energy emissions of both of these phosphors.

In greater detail, with reference to FIGS. 3 and 4, the support medium 27 is in the form of a substantially transparent glass substrate of a ceramic material such as tempered soda lime glass having a light transmission characteristic in excess of 60 percent. The thickness is not critical except that it be of a sufficiency to withstand procesing temperatures without warping or deforming.

Upon this substrate, an inner screen layer 39 in the form of a coating of a radiant energy excitable phosphor 41 is suitably disposed by one of several conventional techniques, such as by settling, slurrying or dusting to provide a screen layer thickness of approximately .001 to .002 inch. An example of a phosphor selected for this application because of its particular hue is a ZnS:Cu material which is responsive to radiant energy excitation in the ultraviolet region and as previously mentioned is JEDEC classified as P2 material. When ultraviolet excited this P2 phosphor produces luminance in the yellow green wavelength portion of the electromagnetic spectrum having a peak spectral output of approximately 5400 angstroms and exhibiting a long buildup with a very long persistence in excess of one second. Under long-wave ultraviolet excitation certain of the copper-activated sulfide phosphors exhibit a much longer buildup and a much longer persistence than when electron excited, as for example the P2 in the previously described embodiment. Another ultraviolet excitable long persistence phosphor suiable for this application is, for example, JEDEC classified P28, a (Zn,Cd)S:Cu yellow-green lurninescing phosphor having a peak spectral output of approximately 5500 angstroms. In the described embodiment, the ZnS:Cu P2 phosphor is utilized, as its peak spectral output lies toward the green wavelength portion of the spectrum and provides an additive hue complementary with a subsequently described substantially red lurninescing phosphor Contained within another layer of the screen structure.

After deposition of the inner screen layer 39 upon the support medium 27', the structure is heated to remove volatile constituents of inner layer screen formation.

The intermediate selective barrier filter layer 43 of a suitable compound to block the passage of electrons and allow the transmission of radiant energy therethrough, is next applied over the inner screen layer 39 by known settling or spraying techniques. An example of a suitable barrier compound is a substantially silicon ceramic material such as 325 mesh 4B leadless glass frit, as manufactured by O. Hommel Company, Philadelphia, Pa., which is suspended in a hexylene glycol-water vehicle for spray deposition. The concentration of the applied frit is such to effect a finished thickness of a sufficiency to be impervious to the electron beam velocities concerned. The formation of the barrier filter is accomplished by firing the frit coated inner screen layer and supporting medium at a suitable temperature for a time period sufficient to melt the frit and form a uniform layer of ceramic glaze.

The outer screen layer 47 is applied as a covering over the glazed barrier layer 43 by a conventional technique such as settling, slurrying or dusting. This layer comprises a uniform mixture of two electron responsive phosphors, one being a first electron excitable phosphor 49 having a radiant energy emission in substantially the ultraviolet wavelength region of the electromagnetic spectrum and the other being a second electron excitable phosphor 51 emitting radiant energy in the visible wavelength portion of the spectrum.

An example of the first electron excitable phosphor 49 having ultraviolet emission is a short persistence 2CaO.Mg.2SiO :Ce material designated by JEDEC number P16. When electron excited, this P16 phosphor emits radiant energy having a peak spectral output of approximately 3800 angstroms which is representative of long wave ultraviolet and below the threshold of spectral response of the human eye. The persistence characteristic is very short being less than one microsecond duration.

' The second electron excitable phosphor 51 having a medium persistence and a radiant energy emission in substantially the visible red wavelength portion of the spectrum may be in the form of a yttrium, gadolinium and/ or lutecium trivalent vanadate or oxide host compound activated by europium and/ or samarium. A suitable example of the above is YVO :Eu material classified by JEDEC as P22 Rare Earth Red. When electron excited, this phosphor produces a bright luminance of a red wavelength hue having a peak spectral output of approximately 6110 angstroms. Since this rare earth phosphor exhibits a medium persistence of several milliseconds duration, it is suitable for screens in tubes whereof the scan rate will be higher than five cycles per second.

Another second electron excitable phosphor not of the rare earth grouping but suitable for this application, is one such as JEDEC classified P19 which is a KMgF zMn material producing luminescence in substantially the orange-red wavelength region having a peak spectral out put of approximately 5900 angstroms. Upon electron excitation, this phosphor exhibits a long persistence in excess of 100 milliseconds which makes it a suitable phosphor component for screens being scanned at rates less than five cycles per second. Thus, in this embodiment the persistence of the respective second electron excitable phosphor is a controlling factor determining the optimum scan rates for which the screen is best suited.

Both of the electron excitable phosphors 49 and 51 which comprise the outer screen layer are of substantially similar particle sizes. Regardless of the technique of screen deposition employed, these two electron responsive phosphors are mixed according to weight proportions, for example, the mixture comprises about to percent of the first or shorter persistence phosphor and about 15 to 40 percent of the second or longer persistence material. The concentration of this mixture which comprises the outer screen layer 37 has an average density to provide a resultant thickness of approximately .001 to .002 inch.

After deposition, the outer screen layer is dried, and the multilayered screen 25 is thence oriented within the face panel portion 19 of the tube envelope which, in turn, is hermetically bonded to the envelope funnel portion 17. The installation of the electron gun 21 and the subsequent processing steps are in accordance with conventional procedure.

Another embodiment of the selective barrier filter layer 43 may be in the form of selected oxides; an example of which is one such as silicon dioxide (SiO When this barrier material is utilized, a film of lacquer material such as a methacrylate toluene formulation, is applied over the formed inner screen layer to provide a substantially smooth base for the barrier layer. This lacquer film is not shown as it is subsequently removed. When the lacquer film has formed, a coating of silicon monoxide (SiO) of substantially uniform thickness is disposed thereover. The respective support medium or face panel, with the partially completed screen structure thereon, is then baked to a suitable temperature for a period of time sufficient to convert the silicon monoxide to silicon dioxide (SiO and to decompose and volatilize the lacquer film therefrom. The silicon dioxide selective barrier filter layer 43 thus formed is impervious to electrons and transmissive to radiant energy. The thickness of this barrier layer is likewise in accordance with the velocity of the respective electron beam employed. Next, the outer screen layer 47 is disposed over the barrier filter layer 43 in the man ner previously described for forming outer screen layer 47, the phosphor constituents being the same. Thus, the two described multilayered screen structures 25' are of similar construction difiering primarily in the composition of the intermediate filter layer.

If enhanced, brightness of the luminescent display is desired, a thin reflective aluminum film, not shown, can be applied over the outer screen layer by a conventional vacuum vaporization technique. The density of this aluminizing film should be in accordance with the velocity of the respective electron beam and of a thickness to permit passage of the beam therethrough without being detrimentally impeditive thereto.

operationally, the aforedescribed multilayered screen is capable of providing a differential color display between fixed and moving objects. With specific reference to FIGS. 3 and 5, there is diagrammatically shown color screen excitation by signal information from a fixed object. The reflected signal or echo from the fixed object is translated by the receiver in a manner that with each successive scan the echo information is superimposed upon that of the previous scan. The electron beam 23 scanning the screen impinges the outer screen layer 47 wherein are disposed the two electron excitable phosphors 49 and 51. The barrier layer 43 therebeneath, being impervious to electron penetration, confines electron excitation to this outer screen layer.

Under electron bombardment, the first electron excitable phosphor 49, aforedescribed as P16 short persistence material, gives off ultraviolet emission 53 which passes through the barrier layer 43 and impinges the radiant energy excitable P2 phosphor material 41 comprising the inner screen layer 39. The P2 being a very long persistence phosphor when excited by the P16 ultraviolet radiation, emits a luminescent yellow-green wavelength 55 Which traverses the support medium 27 and is designated in the fixed object diagrammatic color block 57 as color component A. The electron beam 23 also excites the second electron excitable P22 medium persistence phosphor particles 51 that are disposed in the mixture contiguous to the first electron excitable particles 49. The radiant energy emission thereof is luminescent in the form of a substantially red wavelength 67 which traverses the barrier filter 43, the inner screen layer 39 and the support medium 27, being designated in the diagrammatic color block 57 as color component B. The two color components A and B being superimposed and intermixed are additive to form combined color component C. In this instance, A being substantially yellow-green and B being substantially red, an additive complementary combination of hues is formed to produce a substantially white resultant C; this being the luminescent display indicating the signal reflected from the fixed object.

With particular reference to FIG. 5, there is shown an exaggerated and nonproportioned growth-decay comparison 61 which is not truly representative but serves to illustrate the relationship between buildup times and persistences for the second electron excitable phosphor 51 and the radiant energy excitable phosphor 41 which form the visible complementary components when a fixed object is luminescently portrayed.

The second electron excitable substantially red-emitting phosphor 51 is represented by substantially medium growth and persistive curves 63 and '65 respectively. During the repetitive signal pulses echoed from the fixed object the electron beam excites the second phosphor 51 causing luminescent growth 63. The signal pulses have sufiicient width 69 to permit the luminescence to reach a steady-state brightness level 71 which is a function of the applied voltage and current density. The increase in brightness is substantially linear up to the point of screen saturation or steady-state brightness whereat the luminescent centers available for emission are fully excited so that additional current gives no increase in brightness. The distance between pulses, or pulse separation 70, is not of suflicient duration to allow for complete luminescence decay.

The ultraviolet excitable substantially yellow-green emitting phosphor 41 has a slower growth curve 73 and a longer decay or persistence curve 75 in comparison to the aforementioned phosphor. The width of each signal pulse is not suflicient to permit the full growth in brightness nor is the pulse separation sufiicient to allow for substantial luminescent decay. Therefore, with successive signal pulses supplying additive excitation or reinforcement to the same luminescent centers, growth in brightness increases with each pulse until a steady-state brightness level 71 is reached. For simplification, in this illustration a common steady-state brightness level is shown. Thus, in referring to FIG. 7, the complimentary hues A and B, provided by the phosphors excited by fixed object echoes, form a substantially white C luminescent display 79 in the screen 25' as observed through the face portion 20 of the tube 11. The rate of scan of the radiallymoving trace 81 and the persistences of the additive phosphors are such that at least a portion of the visible luminescence of the fixed object display is maintained between successive scans.

With reference to FIG. 4, the color screen excitation resultant of the echo signal from a moving object is diagrammtaically shown. The electron scanning beam 23 impinges the outer screen layer 47 as previously described, but, as the target object is moving, beam densification moves on the screen in accordance therewith. Therefore, on each succeeding scan the densified beam area is moved from its previous point of impingement, and thus there is little if any superimposed intensification of the beam. The first electron excitbale phosphor 49, being the P16 short persistence material, is impinged by the densified electron beam 23 and excited to give off ultraliovet emission, but with each successive scan the densified portion of the beam shifts to sequentially excite different groups of P16 particles. Since the inner screen layer, comprised of P2 phosphor, requires a long period of build-up there is an insufficient amount of ultraviolet radiation emitted by the P16 particles during a single scan to appreciably excite the P2 phosphor to any degree of luminescence. However, excitation of the substantially red-emitting second electron responsive phosphor 5 1 in the outer screen layer 47 produces a luminescent emission indicated as B in diagrammatic color block '59. The small amount of P2 luminescence is indicated by narrow block A. Since B is predominant, and in this instance is substantially red, the display color evident from a moving object is outstandingly B plus a small amount of additive A to produce a resultant reddish hue B.

For a more detailed explanation of the moving object display, reference is made to FIG. 6, wherein another growth-decay comparison 62 is presented. As with 'FIG. 5, the build-up in brightness of the second electron excitable phosphor 51 represented by growth curve 63, reaches a steady-state level 71 within each pulse width 69. Since the object is moving, dilferent luminescent centers of the phosphor are excited during each successive pulse. For each buildup of excitation, the persistence curve 65 indicates a normal continuance of decay. As previously explained, signal pulse width 69 is insufficient to permit significant brightness growth of the ultraviolet excitable phosphor -41 as indicated by growth curve 6 3. As the echo signal from the moving object also excites different luminescent centers in this phosphor, there is no cumulative buildup and the brightness level 73 never exceeds that of the initial pulse excitation. The result is a very low level of brightness for green hue A. Each successive excitation is accompanied by a normal decay as evidenced by persistence curve Thus, for moving objects, the predominance of the B brightness level 71 provides a screen display in the form of a moving reddish hued luminance B, shown as a pip 85 in FIG. 7. This pip diminishes in accordance with the persistence of the phosphor and rate of scan of the trace 81. There may be occasions when very slow moving objects are observed at a rapid rate of scan, whereupon the information pip rnay evidence a red leading portion, a pinkish body portion, and a dim green trailing portion.

To achieve the desired color differentiation or shift in the display, the proper relationship between scan rate and persistence is important. For example, in a multilayered screen utilizing P2 phosphor in the inner screen layer in conjunction with P16 and P22 Rare Earth Red phosphors in the outer layer, excellent color shift is noted at ten to twenty scans per second; acceptable color shift is apparent down to five scans per second, and little color shift is noted at lower rates of scanning. For scan rates above five cycles per second, the natural persistence of the eye makes the interpreted color a function of the color at the time of excitation. However, for scans slower than five cycles per second, the eye is viewing the color of the decay. To obtain a satisfactory color shift, a phosphor system employing at least two visibly excited phosphors of differing persistences and emissions is needed, The persistences must be such that the varying levels of brightness of both phosphors are still visible at the time of the next scan. In indicating moving objects, the luminescence of the faster of the two phosphors predominates, whereas both luminescent colors are approximately equal and additive for depicting stationary objects.

Comparative luminescent displays are thus provided by a screen comprising a phosphor system wherein information relating to fixed and moving objects is evidenced by easily discernible hues resultant from the utilization of at least two cooperating phosphors having different persistences and luminescent emissions. As a result, the accurate judgment of color difierentiation is facilitated and associated fatigue inducement is reduced to a minimum. Display devices having screens utilizing the phosphor systems herein described and formed by the aforedescribed process readily lend themselves to expeditious and inexpensive fabrication procedures. While substantially white and red luminescent displays have been described, other differential color or luminescent combinations may be utilized to form the screen in keeping with the concept of the invention.

While there have been shown and described what are at present considered the preferred embodiments of the invention, it will be obvious to those skilled in the art that various changes and modifications may be made therein without departing from the scope of the invention as defined by the appended claims.

What is claimed is:

1. A process of forming a cathode ray tube display screen on a substantially transparent supporting surface whereof a plurality of cooperating phosphors have definite persistences and detectably ditferent radiant energy emissions are disposed in at least two related layers, to provide a color display indicating fixed and moving information, said process comprising the steps of:

applying a coating of a radiant energy excitable phosphor on said screen supporting surface to provide a continuous inner screen layer;

applying material means for subsequently forming a heat-converted selective barrier filter layer on said finished inner screen layer;

heating said selective barrier material means, said inner screen phosphor layer, and said supporting medium at a suitable temperature for a period of time sufficient to convert said barrier material means to form said heat-converted filter layer that is substantially transparent to radiant energy emission and impervious to electron penetration, said temperature and time being nondeleterious to the phosphor of said inner screen layer;

applying a mixture of first and second electron responsive phosphors on said heat-converted filter layer to form a continuous outer screen layer, said first phosphor having a radiant energy emission in substantially the ultraviolet region of the electromagnetic spectrum and said second phosphor having a radiant energy emission in the visible wavelength portion of said spectrum; and

heating said multilayered screen and supporting medium at a temperature nondeleterious to said phosphor materials therein to remove volatile materials from said outer screen layer to provide a finished screen.

2. A process of forming a cathode ray tube screen according to claim 1 wherein said inner and outer screen layers are formed to provide a resultant screen layer thickness of approximately .001 to .002 inch; and wherein said first electron responsive phosphor has a substantially short persistence, said second electron responsive phosphor having a peristence longer than that of said first phosphor, and wherein said radiant energy excitable phosphor has a persistence longer than that of said second phosphor.

3. A process of forming a cathode ray tube screen according to claim 1 wherein said selective barrier material means is in the form of leadless glass frit, and wherein said heating of said selective barrier material is of a temperature-time relationship to provide a continuous and uniformly thick filter layer of ceramic glaze covering said inner screen layer,

4. A process of forming a cathode ray tube screen according to claim 3 wherein said leadless glass frit is suspended in a hexylene glycol-water vehicle for uniform application.

5. A process of forming a cathode ray tube screen according to claim 1 wherein said deposition of said outer layer mixture of phosphors comprises weight proportions of about to percent of said first phosphor material and about 15 to 40 percent of said second phosphor material.

6. A process of forming a cathode ray tube screen according to claim 1 wherein said application of said material means for forming said selective barrier filter comprises: applying a film of lacquer material over said inner screen to provide a temporary smooth base for said subsequent barrier layer and applying a uniform coating of substantially silicon monoxide over said lacquer film, and wherein said heating of said selective barrier material means converts the silicon monoxide to silicon dioxide and decomposes and volatilizes said lacquer film therefrom to provide a continuous and uniformly thick heat-converted filter layer of silicon dioxide covering said inner screen layer.

No references cited.

ALFRED L. LEAVITT, Primary Examiner W. F. CYRON, Assistant Examiner US. Cl. X.R. l17-70 

